JavaScript is disabled for your browser. Some features of this site may not work without it.

*** All users be aware: UWSpace has been experiencing unusually long wait times during the depositing process. If you are a graduate student depositing a thesis, it is recommended that while the browser is loading that you do not try to close the connection. If you receive an error or a timeout message, please logout and then log back in. Please do not recreate and resend a new thesis deposit. In most cases, despite the error message, your deposit has successfully been sent to be reviewed. You can verify this by checking under the ‘deposits being reviewed page’. We apologize for the inconvenience. We are working hard to resolve this issue quickly. ***

Study of Au Ball Bond Mechanism and Reliability on Pd/Ni/Cu Substrate

View/ Open

Date

Author

Metadata

Statistics

Abstract

Microelectronic wire bonding is a manufacturing process used to electrically connect integrated
circuits with circuit boards or other substrates. Conventionally, balls are molten at the end of a Au
bonding wire and subsequently bonded on Al metallization of a integrated circuit. However,
Pd/Ni metallization has recently been used for its improved mechanical properties.
The bondability, bonding mechanism, and reliability of Au ball bonds on Pd are studied in this
thesis. The substrates were produced in this project using three different materials. The base material
is polished Cu in the shape of a coupon (1.0 cm × 1.0 cm × 0.5 mm). Cu coupons are plated
with Ni (1.0 μm) using an electroless process, followed by electrolytic plating of a layer of Pd
(0.3 μm), resulting in an arithmetic mean roughness of the surface of 0.08 μm (baseline sample,
sample 0). Higher roughness values of 0.2, 0.4, and 0.5 μm are artificially produced by rolling
(sample 1), sanding (sample 2), and sandblasting (sample 3), respectively, on the Cu surface
before plating Ni and Pd.
A 25 μm diameter Au wire is used for bonding on the polished and roughened substrates with a
process temperature of T = 220 °C, and it was found that ≈ 4 % to ≈ 18 % less ultrasonic amplitude
was required for successful bonding on the roughened substrates compared to the polished
substrate. Bondability is measured by shear testing the ball bonds. An average ball bond strength
achieved on the polished substrate is 130 MPa. This value is lower on the roughened substrate
with the exception of the sandblasted substrate.
Long-term thermal aging at 250 °C was performed with ball bonds on samples 0-3 for durations
of ≈ 300 h. The reliability of the bonds is characterized by non-destructive contact resistance analysis
during aging and destructive cross section analysis after aging. Contact resistance values for
the ball bonds range from 1.6 to 3.5 mΩ at 20 °C before aging, and does not correlate with roughness.
For the baseline sample, contact resistance of the ball bonds decreases during aging by -6 %
(median value), which indicates electrical integrity of the interconnections at high temperature.
This decrease possibly is due to interfacial gap filling by Au or Pd diffusion. In contrast, the contact
resistance increases for the roughened samples 1-3 and changes are 0.4, 5, and 14 %, respectively
(median values). A conclusive explanation for this increase has not yet been found. After
250 h of aging, a TEM analysis showed Au to Pd diffusion in the baseline sample with a diffusion
depth of ≈ 0.1 μm Au. No intermetallics, voids, or contamination is found on the interfaces after
aging according to nanohardness, SEM, and TEM analyses. No bond lift-offs or electrical opens
were found for the aging temperature and durations chosen. No conclusive evidence for the presence
of Au-Pd intermetallics or voids is found.